BACKGROUND OF THE INVENTION The present invention relates to an inlet casing or a suction passage structure which is used for suction of fluid into fluid machinery for boosting up the pressure of fluid through the rotation of an impeller mounted on a rotary shaft, and also to a fluid machinery including a pump, a compressor, a blower or the like, using thereof. In a large-sized suction passage structure, an inlet casing produced as a coupling component for the fluid machinery and used for sucking fluid into a fluid machinery is in general connected to a suction passage which is a concrete construction or the like. The above-mentioned suction passage structure includes a non prewhirl type one in which fluid is led in a form of a suction stream into an inlet opening of fluid machinery, in parallel with a first reference line passing through the center line of a rotary shaft of the fluid machine and extending along the stream of fluid directed to the fluid machine in the suction passage, and a prewhirl type one in which a swirl flow is creased by a swirl portion incorporated in an inlet casing, being orthogonal to a rotary shaft of fluid machinery or which creates a swirl flow swirling around the rotary shaft or an extension or the rotary shaft.
Referring toFIG. 6 which shows a typical nonprewhirl type suction passage structure of a conventional configuration, the suction passage structure includes asuction passage102 arranged orthogonal to a rotary shaft of fluid machinery on the upstream side as viewed in a stream toward the fluid machinery, and aninternal passage104 in asuction casing103, which are arranged, being symmetric with each other to a first reference line C1 (which passes through the center line of arotary shaft101 while it also passes through a heightwise center position of thesuction passage102 or theinternal passage104, and which extends along a stream of fluid toward the fluid machinery in thesuction passage102 and theinternal passage104, a second reference line C2 being orthogonal to the first reference line C1). That is, thesuction passage102 and theinternal passage104 are arranged so that their center lines are substantially superposed on the first reference line C1. Thus, the fluid flowing in parallel with the reference line C1 in thesuction passage102 still flows in parallel with the first reference line C1 in theinternal passage104 even after passing through an inlet opening105 of theinlet casing103 which is a connection between thesuction passage102 and theinlet casing103, and comes to a suction opening through which the fluid is sucked into animpeller106 mounted on therotary shaft101.
Thus, the fluid led into the suction passage structure of the nonprewhirl type flows into the suction opening of the impeller on both sides of the reference line C1 while it interferes with abaffle portion107 incorporating the most downstream part of theinternal passage104, and accordingly, there would be presented a zone where an inflow angle of the fluid at the inlet opening of the impeller and the angle of the inlet opening thereof are different from each other. As a result, there have been raised such disadvantages that a zone where cavitations are caused would be deviated, and further, serious vibration and noise would be possibly caused.
Referring toFIG. 7 which shows a conventional typical configuration of a prewhirl type, a suction passage structure of this type, includes aswirl part113 which is provided in aninternal passage112 of aninlet casing111, which is formed in a spiral shape and with which a swirl stream of fluid is induced, orthogonal to arotary shaft101. Thus, the fluid is sucked into a suction opening of animpeller106, flowing in one way direction, while it interferes with abaffle portion114 provided in the most upstream part of theswirl part113.
The above-mentioned prewhirl type suction passage structure can avoid occurrence of the problem of deviation of a cavitations inducing zone which inherent to the conventional nonprewhirl type one. However, the prewhirl type suction passage structure has raised such a problem that the suction passage and the internal passage can hardly be formed, symmetric to each other with respect to the first reference line C1 as in the nonprewhirl type one. That is, as exhibited in an example shown inFIG. 8, should thesuction passage102 and theinternal passage116 of theinlet casing115 be symmetric to each other, fluid guided through the suction passage120 and theinternal passage116 would flow into the suction opening of theimpeller106 without being subjected to any resistance, and accordingly, it would induce both stream A which is steeply curved in a direction along therotary shaft101 and stream B which crosses therotary shaft101. The stream A is likely to peel off at the suction opening117 of theimpeller106 while the steam B causes a wake at the rear surface part of therotary shaft101 so as to occur a secondary stream, resulting in deterioration of uniformity of the stream at the suction opening117.
Thus, the conventional prewhirl type suction passage structure in general has in general such a structure, as shown inFIG. 7, that thesuction passage102 and theinternal passage112 are formed so as to be asymmetric with each other with respect to the first reference line C1, that is, they are eccentric with each other, in order to obtain uniformity of a stream at the suction opening of theimpeller106. In such an asymmetric configuration, it is required to provide aconnection106 between thesuction passage102 and theinternal passage112 in relatively upstream side part, resulting in occurrence of such a problem that theinlet casing111 inevitably has a large size. Further, the spiral shape of theswirl part113 of theinternal passage112 has to have a complicated curve. As a result, there has been raised such a problem that the design and fabrication thereof becomes complicated, resulting in an increase the costs thereof.
Further, in the prewhirl type suction passage structure, in order to constrain occurrence of both stream A and stream B shown inFIG. 8 so as to enhance the uniformity of the stream, there has been known such a configuration that an element which serves as a resistance against a stream of fluid in theinternal passage112 is provided in the downstream part of theinternal passage112. For example, as such an element, JP-A-51-142101 discloses a protrusion, and JP-A-11-148498 discloses a bevel shape bulge. However, it has not been sufficient with these elements to always main required uniformity of the stream, and accordingly, the suction passage and the internal passage are inevitably formed, symmetric to each other as in the example shown inFIG. 7.
The nonprewhirl type suction passage structure and the prewhirl type suction passage structure have been known as disclosed in JP-A-63-44960 in addition to the above-mentioned JP-A-51-142101 and JP-A-11-148498.
As stated above, there are used both nonprewhirl type suction passage structure and prewhirl type suction passage structure for fluid machinery. The nonprewhirl type suction passage structure may have the suction passage and the internal passage which are symmetric with each other, and accordingly, there may be offered such an advantage the shape of the internal passage can be simple so that it can be easily designed and fabricated but also offered such a disadvantage that a deviation of the cavitations inducing zone likely to occur. Meanwhile, the prewhirl type suction passage structure may avoid occurrence the problem of a deviation of the cavitations inducing zone, but the configuration of the internal passage becomes complicated so as to raise such a problem that the costs thereof is increased in view of its design and fabrication.
BRIEF SUMMARY OF THE INVENTION The present invention is devised in view of the above-mentioned conventional problems, and accordingly, an object of the present invention is to provide a suction passage structure which can effectively avoid occurrence of a deviation of a cavitations inducing zone and as well can simplify the configuration of the internal passage, and to provide fluid machinery using such a suction passage structure.
To the end, according to the present invention, there is provided a suction passage structure provided in fluid machinery for boosting the pressure of fluid through rotation of an impeller mounted on a rotary shaft, for sucking the fluid into the fluid machinery, having an inlet casing including an internal passage connected to a suction passage provided being orthogonal to the rotary shaft on the upstream side in the stream of the fluid directed to the fluid machinery, the internal passage being formed in a spiral shape so as to induce a swirl stream in the fluid, orthogonal to the rotary shaft, characterized in that a rectifying element capable of distributing flow rates in the swirl stream between the center side and the outer peripheral side of the swirl stream in the internal passage, and also capable of causing fluid flowing from the suction passage into the internal passage to deflect the swirl stream into a swirling direction within the internal passage is provided in the vicinity of an inlet of the internal passage.
Further, according to the present invention, the above-mentioned inlet casing is further provided therein with an auxiliary guide vane capable of, in particular, deflecting the fluid, similar to the above-mentioned guide vane, in parallel with the guide vane.
Further, according to the present invention, in the above-mentioned inlet casing, the guide vane has an arcuated rectifying surface.
Further, according to the present invention, in the above-mentioned inlet casing, the internal passage has a swirling part for inducing a swirl stream in the fluid, and an introduction part for introducing the thus swirl stream induced by the swirling part, into the inlet opening of the fluid machinery, and further, a bell-mouth part is formed on the upstream side of the introduction part, being projected in the axial direction of the rotary shaft.
Further, to the end, according to the present invention, there is provided an inlet casing provided in fluid machinery for boosting up a pressure of fluid through rotation of an impeller mounted on a rotary shaft, for sucking the fluid into the fluid machinery, including an internal passage connected to a suction passage incorporated being orthogonal to the rotary shaft on the upstream side of the fluid machinery in a stream of fluid toward the fluid machinery, the internal passage being formed in a spiral shape so as to induce a swirl stream in the fluid, orthogonal to the rotary shaft of the fluid machinery, characterized in that the internal passage has a swirling part for inducing a swirl stream in the fluid, and an introduction part for introducing the swirl stream induced in the swirling par, into the inlet opening of the fluid machinery, a bell-mouth part is provided at an upstream end of the introduction part, being projected in the axial direction of the rotary shaft, the bell-mouth part having a projecting height which is gradually decreased from the upstream side to the downstream side in the direction of the stream of the fluid in the swirling part, the projecting height of a highest projecting part of the bell-mouth part on the upstream side and that of a lowest projecting part thereof on the downstream side has a relationship of b:c which is set to be in a range from 1:1.1 to 1:1.2, where b is a passage width defined between the lower end of the bell-mouth part and the wall surface of the internal passage in the heighest projecting part and c is a passage width defined by the lower end of the bell-mouth and the wall surface of the internal passage in the lowest projecting part.
Further, to the end, according to the present invention, there is provided a suction passage structure provided in fluid machinery for boosting the pressure of fluid through rotation of an impeller mounted on a rotary shaft, for sucking the fluid into the fluid machinery, including a suction passage arranged being orthogonal to the rotary shaft on an upstream side in a stream of the fluid toward the fluid machinery, and an inlet casing having one end connected to the suction passage and the other end connected to the fluid machinery, the inlet casing having an internal passage which is connected to the suction passage and which is formed in a spiral shape so as to induce a swirl stream in the fluid, being orthogonal to the rotary shaft of the fluid machinery, characterized in that the suction passage and the internal passage are arranged so as to cause their respective center axes to be substantially superposed on a first reference line passing the center line of the rotary shaft and a heightwise center position of the suction passage or the internal passage, and extending along a direction of a stream of the fluid toward the fluid machinery in the suction passage, and the internal passage is provided therein with a guide vane capable of distributing flow rates in the swirl stream of the fluid in the internal passage, between a swirl center side of the swirl stream and a swirl peripheral side thereof, and also capable of deflecting the fluid flowing from the suction passage into the internal passage, into the swirling direction of the swirl stream in the internal passage.
To the end, according to the present invention, a fluid machinery for boosting up a pressure of fluid through rotation of an impeller mounted on the rotary shaft, characterized by the above-mentioned inlet casing or suction passage structure.
The guide vane in the present invention, can exhibit a rectifying action for distributing flow rates in the swirl stream in the internal passage on the upstream side of the internal passage, between the swirl center side and the swirl outer peripheral side, and also exhibits a rectifying action for deflecting the fluid into a swirling direction of the swirl stream in the internal passage on the upstream side of the internal passage. Further, with these rectifying action, a rectified swirl stream can be easily formed in the internal passage. As a result, the suction passage and the internal passage in a symmetric configuration can be used for inducing a swirl stream which is effective for preventing occurrence of a deviation of a cavitations inducing zone, that is, a swirl stream which is rectified and which has higher uniformity, and accordingly, the spiral shape of the internal passage can be relative simple, thereby it is possible to facilitate the design and fabrication thereof.
Further, in the present invention, the projecting height of the bell-mouth part which is provided being projected at the upstream end of the introduction part in the internal passage is gradually decreased from the upstream side to the downstream side, and further, the projecting height of the heighest projecting part of the bell-mouth part on the upstream side and that of the lowest projecting part on the downstream side are formed so as to satisfy a predetermined relationship therebetween. Thus, according to the present invention, it is possible to enhance the uniformity of the stream at the suction opening of the fluid machinery so as to effectively prevent occurrence of a deviation of the cavitations inducing zone.
Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGFIG. 1 is a schematic view illustrating a configuration of a suction passage structure in a first embodiment of the present invention, being sectioned in a planar direction;
FIG. 2 is a view illustrating the configuration shown inFIG. 1, being sectioned along a first reference line inFIG. 1;
FIG. 3 is a schematic view illustrating a configuration of a suction passage structure in a second embodiment of the present invention, being sectioned in a plan direction;
FIG. 4 is a view illustrating the configuration shown inFIG. 3, being section along a first reference line inFIG. 3;
FIG. 5 is a view illustrating a configuration of an essential part of a vertical single-side suction type multistage pump;
FIG. 6 is a schematic view illustrating a configuration of a conventional nonprewhirl type suction passage structure, being sectioned in a plan direction;
FIG. 7 is a conventional prewhirl type suction passage structure, being sectioned in a plan direction; and
FIG. 8 is another conventional prewhirl type suction passage structure, being sectioned in a plan direction.
DETAILED DESCRIPTION OF THE INVENTION Explanation will be hereinbelow made of preferred embodiment of the present invention. A configuration of a suction passage structure in a first embodiment is schematically shown inFIGS. 1 and 2.FIG. 1 is a view illustrating the suction passage structure, being sectioned in a plan direction, andFIG. 2 is a view, being sectioned along a reference line C1 inFIG. 1. The suction passage structure in this embodiment is composed of asuction passage2 arranged being orthogonal to arotary shaft1 of rotary machinery, on the upstream side in the direction of a stream of the fluid toward the fluid machinery, in combination of aninlet casing3.
Thesuction casing3 is provided therein with aninernal passage4 which is composed of aswirling part5 in such a spiral shape that a swirl stream orthogonal to the rotary shaft is induced in the fluid introduced through thesuction passage2, that is, a swirl stream rotating around therotary shaft1 or an extension of therotary shaft1 is induced in the fluid, or such a shape that it is curved with its cross-sectional area being gradually decreased from the upstream side to the downstream side, and an introduction part7 (FIG. 2) for introducing the fluid swirled in theswirling part5, into the suction opening6 of the fluid machinery. Further, theinternal passage4 is provided therein with a baffle part8 (only shown inFIG. 1), a bell-mouth part9 (only shown inFIG. 2), a center cone part11 (only shown inFIG. 2), aguide vane12 and anauxiliary guide vane15. It is noted here that theguide vane12 and theauxiliary guide vane15 are omitted fromFIG. 2.
Thebaffle part8 interferes with the fluid flowing downward in theswirling part5 in the most downstream part of the swirling part so as to have a function capable of adjusting a swirling degree of the fluid. Accordingly, thebaffle part8 is formed in such a way that a part of the wall surface of theinternal passage4 is projected in a wedge-like shape. Further thebaffle part8 is provided in the vicinity of a terminal end of theinternal passage4, that is a terminal end of theswirling part5, and of four space zones sectioned by a first reference line C1 (which passes through the center line of therotary shaft1 and which passes through the heightwise center position of thesuction passage2 or theinternal passage4, being extended along the direction of the steam of fluid directed toward the fluid machinery, in thesuction passage2 or the internal passage4) and a second reference line C2 (which is orthogonal to the first reference line C1), the one which is located at the most upstream position of theinternal passage4 is arranged therein with thebaffle part8.
The swirling quantity adjusting function of the above-mentionedbaffle part8 greatly depends upon a position of a distal end thereof. That is, in such a case that the position of the distal end of thebaffle part8 is exhibited by an angle θ between a line horizontally connecting the distal end of thebaffle part8 and the center of therotary shaft8 and the second reference line C2, if the angle θ is too small, the quantity of the swirl flow along the entire periphery of the suction opening6 of the impeller13 (which has leadingedge parts13a) in the fluid machinery is excessive, and on the contrary, if the angle θ is too large, the swirl in theswirling part5 cannot be sufficiently taken. After the analysis of this phenomenon, it has been found hat the distal end of thebaffle part8 has an angle which is preferably in a range from 45 to 90 deg. The bell-mouth part9 has a function capable of preventing occurrence of both stream A and stream B shown inFIG. 8, as explained above. Thus, the bell-mouth part9 is formed so as to have a ring-like shape which surround the rotary axis in a bell-mouth-like manner, and the height thereof in the ring-like shape is set to be uniform in this embodiment. More specifically, the bell-mouth part9 is formed in such a configuration that a part of the wall surface of theinternal passage4 is projected in a ring-like shape having a uniform height and being directed in the axial direction of the rotary shaft in the most upstream end part of theintroduction part7 in a condition in which it extends along therotary shaft1.
Thecenter cone part11 has a function capable of deflecting the stream in theinternal passage4, into an upward direction toward theintroduction part7, and is formed in such a configuration that the wall surface of the internal passage is projected in a cone-like shape so as to extend along therotary shaft1.
The configuration in which theguide vane12 and theauxiliary plate15 are provided in theinternal passage4 is one of essential features of the present invention. Theguide vane12 has a function capable of distributing the flow rates of the fluid in the swirl stream of the fluid in theinternal passage4 between the swirl center side stream (indicated by an arrow F1 inFIG. 1) and the swirl outer peripheral side stream (indicated by an arrow F2 inFIG. 1), and also has a function capable inducing a deflection in the swirling direction of the swirl stream in theinternal passage4 in the fluid flowing from thesuction passage2 into theinternal passage4. Thus, theguide vane12 is formed as a curved shape so as to have acruated rectifying surfaces12fon both sides thereof, and is arranged so as to divide theinternal passage4 along the direction of the stream of the fluid in the vicinity of the inlet of theinternal passage4 or thesuction port14 of theinternal passage4 which is a connection between thesuction passage2 and theinternal passage4, It is noted here that although theguide vane12 is arranged so as to substantially bisect theinternal passage4, this arrangement may be changed depending upon a set distributing rate in the above-mentioned distribution of the flow rate.
Theauxiliary guide vane15 has a main function capable of deflecting the fluid, similar to that of theguide vane12, that is, a function capable of inducting, in the fluid flowing from thesuction passage2 into theinternal passage4, a deflection into the swirling direction of the swirl stream in theinternal passage4. That is, theauxiliary guide vane15 has a function capable of complementing the fluid deflecting function of theguide vane12, and accordingly, the deflection of the fluid flowing from thesuction passage2 into theinternal passage4 into the swirl stream can be smoothened further. Thisauxiliary guide vane15 is formed into a curved plate, similar to theguide vane12, so as to have arcuated rectifying surfaces15fon both side of thereof, and in this embodiment shown in this embodiment, it is laid in parallel with theguide vane12. However, this arrangement and the curved shape can be changed depending upon the positional relationship between theguide vane12 and thebaffle part8 and a configuration thereof.
One of the essential features of the present invention is such that thesuction passage2 and theinternal passage4 are both have a symmetric configuration. That is, the respective center lines2c,4cof thesuction passage2 and theinternal passage4 are substantially superposed on the first reference line C1. This configuration relates to a configuration for providing theguide vane12 and theauxiliary plate15, as explained later.
In the suction passage structure in the first embodiment as stated above, the fluid flowing from thesuction passage2 into theinternal passage4 by way of thesuction port14, is subjected, by theguide vane12 in the vicinity of thesuction port14, to the rectifying action for distributing flow rates in the swirl stream of the fluid in theinternal passage4 between the swirl center side stream and the swirl outer peripheral side thereof, and by bothguide vane12 andauxiliary guide vane15, to the rectifying action for deflecting the fluid into the swirling direction of the swirl stream in the swirlingpart5 of theinternal passage4. Further, with these rectifying actions, a rectified swirl stream can be easily formed in the swirlingpart5. Thereby it is possible to offer the following advantages: thesuction passage2 and theinternal passage4 in a symmetric configuration can be used for obtaining a swirl stream effective for preventing a deviation of a cavitations inducing zone or a rectified and uniform high swirl stream, and accordingly, it is possible to allow the spiral shape of the swirlingpart5 to have a relative simple configuration as in the embodiment shown inFIG. 1, thereby the design and the fabrication thereof can be facilitated.
The fluid having been subjected to the rectifying actions by theguide vane12 and theauxiliary guide vane15 is turned into a swirl stream so as to flow downward through the swirlingpart5, then flows into theintroduction part7 while it is exerted with upward deflection by thecenter cone part11, and is finally sucked into theimpeller13 of theflid machinery13 by way of thesuction opening6. While the fluid flows as stated above, the fluid interferes with the bell-mouth part9 so as to be exerted thereto with a resistance. The resistance exerted by the bell-mouth9 constrains occurrence of both stream A and stream B so as to serve to make the stream uniform in thesuction opening6, and in cooperation with the rectifying actions by theguide vane12 and theauxiliary guide vane15 as stated above, the uniformity of the stream of the fluid can be further enhanced.
Referring toFIGS. 3 and 4 which shows a configuration of a suction passage structure in a second embodiment of the present invention, the configuration of this embodiment is similar to that of the first embodiment. Explanation will be made of differences of the configuration of this embodiment from that of the first embodiment. It is noted in the figures that like reference numerals are used to like parts to those in the first embodiment.
This embodiment is different from the first embodiment such that abaffle part21 as a component corresponding to thebaffle part8 shown inFIG. 1 is provided while a bell-mouth part22 as a component corresponding to the bell-mouth part9 shown inFIG. 1 is provided.
Thebaffle part21 has a projecting height which is lower than that of thebaffle part8. Specifically, the projecting height of thebaffle part8 shown inFIG. 1 is set so that the distal end of thebaffle part8 is overlapped more or less with the contour of theimpeller13, but thebaffle part21 has a distal end part which is slightly spaced from the contour of theimpeller13, more or less. The distal end part of thebaffle part21 which is in a wedge-like shape has an obtuse angle in comparison with that of thebaffle part8. Specifically, the angle of the distal end part of thebaffle part21 is obtained by slightly cutting the distal end part of thebaffle pat8 having an acute angle as indicated by a dotted line inFIG. 3. Such abaffle part21 can moderate the interference with the fluid in the swirling quantity adjusting function, thereby it is possible to reduce disturbance of the swirl stream caused by the interference. In order to more effectively exhibit the advantages of thebaffle part21, thebaffle part21 is formed into an arcuated shape along the spiral shape of the swirlingpart5, and further, the edge of the of the distal end part is preferably formed into an arcuted shape. Thebaffle part21 as stated above has a position of a distal end part having an angle which is a range from 45 deg. to 90 deg.
The bell-mouth part22 has a configuration basically similar that of the bell-mouth part9, except that it has an asymmetric configuration so as to decrease its projecting height thereof gradually from the upstream side to the downstream side of the swirl stream. With the configuration of this bell-mouth part22, the fluid can be exerted thereto with a large resistance in the upstream part of the swirl stream by apart22aof the bell-mouth part22 which has a higher projecting height, thereby it is possible to effectively prevent occurrence of both stream A and stream B shown inFIG. 8. Meanwhile, the fluid is exerted thereto with a relatively small resistance in the downstream part of the swirl stream by apart22bof the bell-mouth part22 which has a lower projecting height, thereby it is possible to smoothly suck the fluid into thesuction opening6 of theimpeller13.
As stated above, the effect obtained by the bell-mouth part22 of the asymmetric configuration is dependent upon a ratio of a passage area of the lower part of the bell-mouth part22 (which is given by the passage width defined between the distal end of the bell-mouth part22 and the wall surface of theinternal passage4 opposed to the former) to a passage area d of thesuction opening6 of the impeller13 (which area is actually obtained by subtracting an area occupied by the rotary shaft1). That is, if the passage area of the lower part of the bell-mouth part22 is too narrow in comparison with the passage area of the suction opening, specifically if the ratio of the passage area of the lower part of the bell-mouth part22 which is in particular given by a passage width indicated by b inFIG. 4 to the passage area d of the suction opening, is less than 3, the flow rate becomes too high in the lower part of the bell-mouth part22 so as to cause a loss to increase, and on the contrary, if the passage area of the lower part of the bell-mouth part22 is wide in comparison with the passage area d of the suction opening, specifically if the ratio of the passage area of the lower part of thebell mouth part22 to the passage area d of the suction opening is greater than 4, no effect by the bell-mouth part22 of the asymmetric configuration can be obtained. Thus, it is preferable to set the projecting height of the bell mouth part22 (which is an averaged height) so that the ratio between the passage area of the lower part of the bell-mouth part22 with respect to the passage area d of the suction opening falls in a range from 1:3 to 1:4.
Further, the effect of the bell-mouth part22 of the asymmetric configuration is dependent upon the ratio between the height of thepart22ahaving the highest projecting height and that of thepart22bhaving the lowest projecting height, in other words, the ratio between the passage width b defined between the distal end of thepart22ahaving the highest projecting height and the wall surface of theinternal passage4 opposed to thereto and the passage width c defined between the distal end of thepart22bhaving the lowest projecting height and the wall surface of theinternal passage4 opposed thereto. That is, if the ratio of the passage width c of the lower part of the bell-mouth part22 in the part having the lowest projecting height to the passage width b of the lower part of the bell-mouth part22 in the part having the highest projecting part is too large, that is, it is greater than 1.2, the resistance in thepart22ahaving the highest projecting height becomes excessively large while the inflow of the fluid into thesuction opening6 in thepart22bhaving the lowest projecting height becomes relatively large. As a result, the uniformity along the entire periphery of thesuction opening6 is deteriorated. The ratio between the passage width c of the lower part of bell-mouth part to the passage width b of the lower part of the bell-mouth part is too small, that is, specifically, it is smaller than 1.1, the resistance in thepart22ahaving the highest projecting height is too small while the inflow of the fluid into thesuction opening6 in the part having the part having the lowest projecting height becomes relatively small. As a result, the uniformity around the entire periphery of thesuction opening6 is similarly deteriorated. Thus, the projecting height of the bell-mouth part22 is set so that the ratio of the passage width c of the lower part of the bell-mouth part to the passage width b of the lower part of the bell-mouth part falls in a range from 1:1.1 to 1:1.2. It is noted that the passage width b and the passage width c give passage areas of the associated parts of the lower part of the bell-mouth part. In other words, the passage width b and the passage width c can correspond to the passage areas of the associated parts of the lower part of the bell-mouth part.
It is noted here that although explanation has been made of the embodiments in which the single side suction type spiral pump is used as an example, and in which the rotary shaft is extended into the inlet casing for the purpose of convenient explanation, the present invention should not be limited to these embodiments, but the present invention can be applied in any or various fluid machinery which requires uniformity at the suction opening of the impeller.
Next, explanation will be hereinbelow made of a third embodiment of the present invention. In this embodiment, the configuration of the suction passage structure in the second embodiment is applied in a vertical single side suction type multi-stage pump. Referring toFIG. 5 which shows a configuration of an essential part of the vertical single side suction type multi-stage pump, the vertical single side suction type multi-stage pump incorporates arotary shaft32 which is journalled at opposite ends thereof byradial bearings31, the pressure of fluid is boosted up through rotation of impellers33 (which has leadingedges33a) at multi-stages (four stages in the figure) mounted on therotary shaft32. Specifically, the fluid whose pressure has been boosted up by one of theimpellers33 passes through adiffuser34, radially outward from therotary shaft32 side, and then passes through areturn35 where it is deflected into a stream in a radially inward direction so as to be led into theimpeller33 at the next stage. With the repetitions of the above-mentioned steps, the fluid is boosted up by theimpellers33. High pressure fluid boosted up by theimpeller33 at the final stage, is led through thediffuser34 and is recovered in adischarge casing36 from which it is led to a discharge opening (which is not shown).
The vertical single side suction type multi-stage pump is integrally incorporated thereto with theinlet casing3 in the suction passage structure in the second embodiment, and thesuction passage2 is connected to theinlet casing3 through the intermediary of thesuction port14. The configuration of the suction passage structure composed of thesuction passage2 and theinternal passage4 have been already explained in the second embodiment, and accordingly, the explanation thereto will be omitted in this embodiment.
According to the present invention, the suction passage structure constrains occurrence of a deviation of a cavitations inducing zone as the suction of fluid in fluid machinery, and further a configuration of an internal passage in a prewhirl type suction casing can be simplified. The invention as detailed hereinabove can be widely used in the technical field of the fluid machinery.
It should be further understood by those skilled in the art that although the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.